Electronic catheter stethoscope

ABSTRACT

An electronic catheter stethoscope measures and analyzes acoustic fields and dynamic pressure variations in the gaseous or liquid fluid inside a conventional medical catheter that is positioned in a patient&#39;s urologic, digestive, reproductive, cardiovascular, neurological or pulmonary system. Measurement transducers are installed in a housing connectable to multiple preselected medical catheters. The transducers detect bodily functions that are transmitted to the preselected catheter from within the body. The transducers, housing, electrical interface and signal processing electronics are positioned outside the body.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of currently pending International Application No. PCT/US2011/028519, filed Mar. 15, 2011, entitled “Electronic Catheter Stethoscope” herein incorporated by reference, which claims priority to U.S. provisional patent application No. 61/313,921, having the same title, filed on Mar. 15, 2010, which is herein incorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to medical devices. More particularly, it relates to a device that monitors, measures and analyzes a variety of bodily functions.

2. Description of the Prior Art

Fetal heart tones and labor contractions are measured using sensors or instruments that are placed externally on the mother's body. This method is illustrated in prior art FIG. 1.

U.S. patent application Nos. 2009/0259133A1 and 2009/0192396A1 disclose the positioning of electrocardiogram (ECG) electrodes on the mother's abdomen to detect the fetal heart tone. Systems of this type rely on the detection of electrical impulses that originate from the heart muscles of the mother, the fetus, or both, myoelectric sensors capable of detecting muscle contractions, or Doppler ultrasound to detect heart movement.

There are a number of disadvantages to placing external monitors on the mother's body to monitor the fetal heart rate and intrauterine contractions as follows:

The fetal heart rate sensor performance can be compromised by:

-   -   Poor placement of sensors on mother's abdomen     -   Excessive amniotic fluid     -   Obese mother     -   Small or multiple babies     -   Movement of the baby out from under the sensor or sensors     -   Detection of mother's pulse instead of baby's pulse     -   The sensors are prone to falling off or moving, so the mother         must remain still

The contraction sensor performance is compromised because it:

-   -   Can only detect frequency and duration of contractions     -   Cannot provide direct measurement of intrauterine pressure         intensity     -   Cannot provide comparative measurements of a series of         contractions

Fetal heart tones and labor contractions are also measured using sensors or instruments that are positioned in the mother's uterus and on the baby's head. This method is illustrated in FIG. 2.

There are a number of disadvantages to using an internal monitor installed within the mother's uterus or on the baby as follows:

-   -   The cervix must be dilated prior to placement of the monitors     -   Membranes must be ruptured to place monitor which commits         mother/baby to delivery     -   Increased risk of infection to the baby     -   Increased risk of bruising of the baby's scalp     -   Possible uterine perforation/rupture     -   Potential for placental separation

U.S. Pat. No. 6,434,418 discloses an instrumented catheter inserted into the bladder or rectum including a catheter balloon instrumented with pressure or myoelectric sensors to measure intrauterine pressure or detect contractions and a catheter tip instrumented with microphone, electrode or Doppler ultrasound probe to measure fetal heart rate. This method requires placement of electronic instrumentation within the body, it requires high-cost manufacturing of catheters having electronic instruments within them, it requires additional and non-standard procedures and personnel for placement of the catheter, and it requires that the entire catheter system be sterilized for re-use.

There are no known commercial products or technologies that non-invasively detect physiologic bladder changes during surgical procedures or provide direct measurement of acoustic fields and pressure variations within the bladder that could suggest bladder or ureteral injury.

Conventional blood pressure monitoring devices provide only pressure time histories of blood flow and do not measure to a sufficiently high frequency range acoustic or pressure variations that can be used to detect cardiovascular anomalies. Patent applications such as U.S. patent application No. 2010/00030095 disclose acoustic monitors and electronic stethoscopes to detect cardiovascular anomalies. However, the known devices do not provide direct measurement of acoustic fields and dynamic pressure variations of the blood within the blood vessels.

The known commercial products or technologies that enable direct measurement of acoustic fields and dynamic pressure variations due to respiration and blood flow within the lungs require the installation of measurement transducers within the lungs.

The prior art devices that enable direct measurement of acoustic fields and dynamic pressure variations due to digestion and blood flow within the stomach or upper digestive tract require the installation of measurement transducers within the stomach or upper digestive tract.

Commercial products or technologies that enable direct measurement of acoustic fields and dynamic pressure variations due to digestion and blood flow within the colon require the installation of measurement transducers within the colon.

What is needed, then, is a medical device that enables direct measurement of acoustic fields and dynamic pressure variations within such body parts without requiring that transducers by positioned within said body parts.

However, in view of the art considered as a whole at the time the present invention was made, it was not obvious to those of ordinary skill in the art that a medical device that enables direct measurement of acoustic fields and dynamic pressure variations within body parts without requiring transducers positioned within said body parts was needed nor was it obvious how such a device could be provided.

SUMMARY OF THE INVENTION

The present invention includes an electronic catheter stethoscope that enables the measurement and analysis of acoustic fields and dynamic pressure variations in the gaseous or liquid fluids inside a standard medical catheter that may be installed in a patient's urologic, digestive, reproductive, cardiovascular, neurological or pulmonary system to monitor a patient's heart beat, fetal heart beat, breathing, labor contractions, ureteral flow and physiology of the bladder, digestive, urologic, pulmonary, cardiovascular and neurologic systems.

Measurement transducers are installed in a housing that is connectable to preselected conventional medical lines or catheters, such as urinary (foley), intravenous, arterial, cardiac or pulmonary catheters. The transducers detect a variety of bodily functions that may be transmitted to the catheters from within the body, such as patient heart beat, fetal heart beat, breathing, blood flow, labor contractions, ureteral flow and physiology of the bladder and other acoustic fields and dynamic pressure variations associated with the digestive, urologic, pulmonary, cardiovascular and neurologic systems.

The transducers, housing, electrical interface and signal processing electronics are positioned outside the body together with a variety of commercially available sterilized catheters that are inserted into the body. This facilitates use, improves patient safety, reduces the probability of infection, and eliminates the need for special procedures or personnel to install such off-the-shelf devices inside the body.

The transducer signals are stored by a data acquisition device for subsequent processing, analysis or display, or the signals may be processed, analyzed and displayed immediately to provide real time physiological monitoring.

More particularly, the novel method for measurement and analysis of bodily functions includes the steps of connecting a housing to the proximal end of a preselected medical catheter, inserting a distal end of the preselected medical catheter into a patient's body while maintaining the proximal end and the housing outside the patient's body, positioning at least one transducer within the housing so that said at least one transducer is in fluid communication with gaseous or liquid fluids in the patient's body, monitoring acoustic fields and pressure variations of liquid or gaseous fluids within the preselected medical catheter due to a variety of bodily functions, including patient heart beat, fetal heart beat, breathing, labor contractions, ureteral flow and physiology of the bladder, digestive, urologic, pulmonary, cardiovascular and neurologic systems, providing a data acquisition system for conditioning, amplifying and converting analog measurement signals generated by said at least one transducer to digital signals, positioning said data acquisition system externally of the housing, and providing electrical communication between said at least one transducer and said data acquisition system.

Further novel steps include mounting a Luer-type connector on a distal end of the housing, opening a valve mounted on the proximal end of the preselected catheter by employing the Luer-type connector to connect the housing to the proximal end of the preselected medical catheter, mounting a purge/fill valve on the housing so that gaseous or liquid fluids may be introduced into or purged from the housing, filling or purging the housing and preselected medical catheter with gaseous or liquid fluid when the valve mounted on the proximal end of the preselected catheter is opened by the Luer-type connector, and selecting said preselected medical catheter from a group of medical catheters including urinary (foley) catheters, intravenous catheters, arterial catheters, cardiac catheters, pulmonary catheters, bronchial catheters, esophageal catheters, and colon catheters.

In addition to post-attachment filling, the invention also includes the steps of filling the catheter without the device attached, followed by attaching the device so that the Luer-type connector provides fluid communication with the transducers.

Moreover, the invention also includes the “open-channel” case in which a Luer-type connector rather than a Luer-actuated valve is mounted on the proximal end of the catheter. The device is then attached with a Luer-activated valve on its proximal end and used for filling.

The novel method further includes the steps of providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both selecting as said preselected medical catheter a urinary catheter having a balloon formed integrally therewith, connecting the housing to a proximal end of the urinary catheter, positioning a distal end of the urinary catheter within the bladder of a patient, and directly measuring acoustic fields and dynamic pressure variations in the gaseous or liquid fluid that fills the balloon with said at least one acoustic transducer and a least one pressure transducer.

The novel method also includes the steps of providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both, selecting as said preselected medical catheter an intravenous catheter or arterial line, and monitoring and measuring fetal heart rates, fetal heart tones and a mother's heart rate with said at least one acoustic and pressure measurement transducers.

Further method steps include providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both, selecting a urinary catheter as the preselected medical catheter, placing the drainage tube of the urinary catheter within the bladder of a patient, directly measuring acoustic fields and dynamic pressure variations in the bladder by connecting the housing to a proximal end of the drainage tube, and detecting ureteral flow and damage to the bladder wall which may occur during surgery with said at least one acoustic transducer and said at least one pressure transducer.

Additional method steps include providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both, measuring acoustic fields and dynamic pressure variations in the cardiovascular system due to beating of the heart, vascular disease or other anomalies that can be detected through changes in blood flow by connecting the housing to the venous or arterial entry port of a peripherally inserted catheter, central catheter, or subcutaneous implantable port or manifold used in medical procedures.

Still further novels steps include providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both, selecting a bronchial catheter as said preselected medical catheter, inserting a distal end of said bronchial catheter into a bronchial tube of a patient or any branches of said bronchial tube, and measuring acoustic fields and dynamic pressure variations in the lungs during breathing by connecting said housing to a proximal end of said bronchial catheter.

Another novel method includes the steps of providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both, selecting a esophageal catheter as said preselected medical catheter, inserting a distal end of said esophageal/gastric catheter into the esophagus tube of a patient, and measuring acoustic fields, dynamic pressure variations and contractions in the stomach or upper digestive tract due to digestion by connecting the housing to the proximal end of said esophageal/gastric catheter.

Yet another novel method includes the steps of providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both, selecting a colon catheter as said preselected medical catheter, inserting a distal end of said colon catheter into the colon of a patient, and measuring acoustic fields, dynamic pressure variations and contractions in the colon due to digestion by connecting said housing to the proximal end of said colon catheter.

All of the novel method steps include the step of providing said electrical communication through a wired or wireless transmission of transducer signals to said data acquisition system.

The novel method may also include the step of mounting a membrane within the housing to shield said at least one transducer from bodily fluids while allowing passage of acoustic and pressure variations and disturbances in the blood flow.

A data analysis system may also be provided and connected to said data acquisition system for processing digital measurement signals and for removing and isolating extraneous noises. The digital measurement signals are processed by said data acquisition system to monitor and analyze a variety of bodily functions, including patient heart beat, fetal heart beat, breathing, labor contractions, ureteral flow and physiology of the bladder, digestive, urologic, pulmonary, cardiovascular and neurologic systems. Raw or processed measurement signal data may be stored in a digital memory device and said stored raw or processed measurement signal data may be displayed in a graphical display.

The data acquisition system may be provided in the form of a hand-held computational device. Moreover, the housing may be covered with sound absorbing materials to shield it from ambient noise. Ambient noise may be actively cancelled by employing at least one external microphone in combination with said at least one transducer. Extraneous body noises or pressure fluctuations may be actively cancelled by positioning at least one acoustic or at least one pressure measurement transducer externally on a patient's body in combination with said at least one transducer.

The housing and said at least one transducer may be sterilized for subsequent use. The housing and said at least one transducer may also be provided in disposable form and said at least one transducer may be provided in the form of a Doppler ultrasound transceiver. The housing may also be unsterilized but connected with a disposable sterilized connector and covered with a sterile, protective sheath.

An important object of this invention is to monitor a plurality of bodily functions during labor or surgical procedures without requiring the introduction of monitoring devices into the body of a patient.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the invention, reference should be made to the following detailed description, taken in connection with the accompanying drawings, in which:

FIG. 1 is a diagram of a prior art external fetal monitor and its placement in monitoring a fetus;

FIG. 2 is a diagram of a prior art internal fetal monitor and its placement in monitoring a fetus;

FIG. 3 is a diagram of an electronic catheter stethoscope;

FIG. 4 is a diagram of the electronic catheter stethoscope used for a urinary (foley) catheter application; and

FIG. 5 is a perspective view of an electronic catheter stethoscope used for urinary (foley) catheter applications.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The novel electronic catheter stethoscope is illustrated in FIG. 3. Housing 1, made from medical-grade plastic or metal or similar material, contains transducers 2. These transducers may include at least one acoustic measurement device such as a microphone or at least one pressure measurement device, or both, that operate in gaseous or liquid fluid.

Housing 1, transducers 2, electrical interface 7 and signal processing electronics 8 of this invention are used outside the body together with a variety of commercially-available off-the-shelf sterilized catheters that are inserted into the body. This facilitates use, improves patient safety, reduces the probability of infection, and eliminates the need for special procedures or personnel to install such devices inside the body.

The transducer signals may be stored by data acquisition device 8 for subsequent processing, analysis or display, or they may be processed, analyzed and displayed immediately to provide real-time physiological monitoring.

Housing 1 incorporates a standard medical Luer-type connector 3 that enables its connection to a variety of preselected tubes, valves and manifolds used in a variety of standard medical catheters or lines 5, such as urinary (foley), intravenous, arterial, bronchial/pulmonary, esophageal and colon catheters.

Luer-type connector 3 contains the gaseous fluid within the catheter system and also enables the opening of valve 4 that is installed in conventional medical catheter 5. Connector 3 enables a direct connection between transducers 2 and the liquids/gases or bodily fluids, or both, within catheter tube 5. Fill/Purge valve 6 enables filling and purging of gaseous or liquid fluids into and from housing 1, respectively.

Transducers 2 have sufficient dynamic range, frequency response and sensitivity to measure acoustic fields and dynamic pressure variations in the gaseous or liquid fluids inside catheter tube 5 that are present due to a variety of bodily functions, including patient heart beat, fetal heart beat, breathing, labor contractions, ureteral flow and physiology of the bladder, and other acoustic fields and dynamic pressure variations associated with the digestive, urologic, pulmonary, cardiovascular and neurologic systems.

Transducers 2 are connected through electronic interface 7 to data acquisition system 8 that acquires, analyzes, stores and displays the transducer data.

The novel method for monitoring labor and delivery includes the step of installing the novel electronic catheter stethoscope onto the external (proximal) end of a conventional urinary (foley) catheter, the distal end of which is placed within the mother's bladder, rectum or uterus during labor (FIGS. 4 & 5) for purposes of monitoring the fetal heart tones and mother's labor contractions. Due to the close anatomic relationship of the bladder, rectum or uterus to the fetus, information obtained from within these organs provide a more accurate way to measure uterine contractions and fetal heart tones.

The novel device is installed on the catheter balloon fill line so that catheter balloon 9 is in intimate contact with the mother's bladder. Catheter balloon 9 responds to sound and vibration from within the bladder due to the fetal heart beat, mother's heart beat and intrauterine contractions. Balloon 9 transmits this sound and vibration to the liquid or gaseous fluid that fills it, and through catheter tube 5 having tip 5 a to the transducer or transducers 2. The transducer measurement device or devices 2 sense acoustic fields and dynamic pressure variations within the gaseous or liquid fluid, and convert said variations into corresponding varying electrical signals that are analyzed in data acquisition device 8.

Advantages of the invention compared to the prior art for labor and delivery monitors include the following:

-   -   The monitoring system is external to the body. There is         therefore less risk of infection or injury to the patient or         baby as compared to internal monitors, and replacement of the         device can easily be accomplished if malfunction occurs.     -   Use of the device does not alter normal medical protocols or         interfere with standard procedures.     -   The device allows the monitoring of intrauterine contractions         and fetal heart tones with a single instrument instead of two         separate monitoring systems.     -   The device is less susceptible than external monitors to         mother's and baby's movement, excessive amniotic fluid and the         mother's obesity. This enables continued monitoring of the fetal         heart rate and intrauterine contractions on a wide range of         medical conditions and does not require immobilization of the         mother during usage.     -   The device detects strength of contractions as well as         contraction frequency and duration.     -   The device does not commit the mother into labor and therefore         can be used to monitor the baby internally at any time.

The novel method for monitoring bladder physiology includes the step of monitoring and detecting ureteral flow, urinary injury and abnormalities of bladder physiology during pelvic and urological surgery by means of the electronic catheter stethoscope. The electronic catheter stethoscope is connected to the valve that is used to fill the catheter balloon or on the catheter drainage line.

The electronic catheter stethoscope may also be connected to a catheter balloon fill valve. The catheter balloon is then positioned for intimate contact with the patient's bladder. Transducer measurement device or devices 2 sense acoustic fields and dynamic pressure variations within the gaseous or liquid fluid that is used to fill the catheter balloon, as the balloon responds to and transmits sound and vibration from within the bladder due to urine flow from the ureters and potential damage to the bladder wall which may occur during surgery.

If the electronic catheter stethoscope is connected to the catheter drainage line, transducers 2 directly sense potential damage to the ureters or bladder which may occur during surgery. In this case, the transducers sense a large increase in the acoustic levels from within the bladder due to damage of the bladder or ureter walls.

The novel method for cardiovascular monitoring includes connection of the electronic catheter stethoscope to an intravenous catheter or arterial line to monitor dynamic blood pressure and to measure and analyze heart tones, vascular changes, or both for the detection of heart valve anomalies, heart murmurs, valvular leaks, or vascular changes suggestive of cardiovascular disease or tumors.

The electronic catheter stethoscope is connected to the venous or arterial entry port of a peripherally inserted catheter, central catheter, or subcutaneous implantable port or manifold used in medical procedures in order to measure acoustic fields and dynamic pressure variations in the cardiovascular system due to beating of the heart, vascular disease or other anomalies that can be detected through changes in blood flow.

The novel method for bronchial monitoring includes the step of connecting the electronic catheter stethoscope to a bronchial or pulmonary catheter to monitor and analyze acoustic fields and dynamic pressure variations associated with respiration and blood flow within the pulmonary system.

The novel method for esophageal/gastric monitoring includes the step of connecting the electronic catheter stethoscope to an esophageal or gastric catheter or tube to monitor and analyze acoustic fields and dynamic pressure variations in the stomach or upper digestive tract due to digestion.

The novel method for colon monitoring includes the step of connecting the electronic catheter stethoscope to a colon catheter to monitor and analyze acoustic fields and dynamic pressure variations in the colon due to digestion.

It will be seen that the advantages set forth above, and those made apparent from the foregoing description, are efficiently attained and since certain changes may be made in the above construction and method steps without departing from the scope of the invention, it is intended that all matters contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.

It is also to be understood that the following claims are intended to cover all of the generic and specific features of the invention herein described, and all statements of the scope of the invention which, as a matter of language, might be said to fall there between. 

1. A method for measurement and analysis of bodily functions, comprising the steps of: connecting a housing to the proximal end of a preselected medical catheter; inserting a distal end of said preselected medical catheter into a patient's body while maintaining said proximal end and said housing outside the patient's body; positioning at least one transducer within said housing so that said at least one transducer is in fluid communication with gaseous or liquid fluids in said patient's body; monitoring acoustic fields and pressure variations of liquid or gaseous fluids within the preselected medical catheter due to a variety of bodily functions, including patient heart beat, fetal heart beat, breathing, labor contractions, ureteral flow and physiology of the bladder, digestive, urologic, pulmonary, cardiovascular and neurologic systems; providing a data acquisition system for conditioning, amplifying and converting analog measurement signals generated by said at least one transducer to digital signals; positioning said data acquisition system externally of said housing; and providing electrical communication between said at least one transducer and said data acquisition system.
 2. The method of claim 1, further comprising the step of: mounting a Luer-type connector on a distal end of said housing; opening a valve mounted on said proximal end of said preselected catheter by employing said Luer-type connector to connect said housing to said proximal end of said preselected medical catheter.
 3. The method of claim 2, further comprising the steps of: mounting a purge/fill valve on said housing so that gaseous or liquid fluids may be introduced into or purged from said housing.
 4. The method of claim 3, further comprising the steps of: filling or purging said housing and preselected medical catheter with gaseous or liquid fluid when said valve mounted on said proximal end of said preselected catheter is opened by said Luer-type connector.
 5. The method of claim 1, further comprising the steps of: selecting said preselected medical catheter from a group of medical catheters including urinary (foley) catheters, intravenous catheters, arterial catheters, cardiac catheters, pulmonary catheters, bronchial catheters, esophageal catheters, and colon catheters.
 6. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting as said preselected medical catheter a urinary catheter having a balloon formed integrally therewith; connecting said housing to a proximal end of said urinary catheter; positioning a distal end of said urinary catheter within the bladder of a patient; and directly measuring acoustic fields and dynamic pressure variations in the gaseous or liquid fluid that fills said balloon with said at least one acoustic transducer and a least one pressure transducer.
 7. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting as said preselected medical catheter an intravenous catheter; inserting a distal end of said intravenous catheter into a blood vessel; and monitoring and measuring fetal heart rates, fetal heart tones and a mother's heart rate with said at least one acoustic and pressure measurement transducers by connecting said housing to a proximal end of said heart-monitoring catheter.
 8. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting as said preselected medical catheter an arterial line; inserting a distal end of said arterial line into a blood vessel; and monitoring and measuring fetal heart rates, fetal heart tones and a mother's heart rate with said at least one acoustic and pressure measurement transducers by connecting said housing to a proximal end of said heart-monitoring catheter.
 9. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting a urinary catheter as the preselected medical catheter; placing the drainage tube of said urinary catheter within the bladder of a patient; and directly measuring acoustic fields and dynamic pressure variations in the bladder by connecting said housing to a proximal end of said drainage tube.
 10. The method of claim 9, further comprising the steps of: detecting ureteral flow and damage to the bladder wall which may occur during surgery with said at least one acoustic transducer and said at least one pressure transducer.
 11. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; measuring acoustic fields and dynamic pressure variations in the cardiovascular system due to beating of the heart, vascular disease or other anomalies that can be detected through changes in blood flow by connecting said housing to the venous or arterial entry port of a peripherally inserted catheter, central catheter, or subcutaneous implantable port or manifold used in medical procedures.
 12. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting a bronchial catheter as said preselected medical catheter; inserting a distal end of said bronchial catheter into a bronchial tube of a patient or any branches of said bronchial tube; measuring acoustic fields and dynamic pressure variations in the lungs during breathing by connecting said housing to a proximal end of said bronchial catheter.
 13. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting a esophageal catheter as said preselected medical catheter; inserting a distal end of said esophageal catheter into the esophagus tube of a patient; measuring acoustic fields, dynamic pressure variations and contractions in the stomach or upper digestive tract due to digestion by connecting said housing to the proximal end of said esophageal catheter.
 14. The method of claim 1, further comprising the steps of: providing said at least one transducer in the form of at least one acoustic transducer or at least one pressure transducer, or both; selecting a colon catheter as said preselected medical catheter; inserting a distal end of said colon catheter into the colon of a patient; measuring acoustic fields, dynamic pressure variations and contractions in the colon due to digestion by connecting said housing to the proximal end of said colon catheter.
 15. The method of claim 1, further comprising the steps of: providing said electrical communication through a wired or wireless transmission of transducer signals to said data acquisition system.
 16. The method of claim 1, further comprising the step of: mounting a membrane within said housing to shield said at least one transducer from bodily fluids while allowing passage of acoustic and pressure variations and disturbances in the blood flow.
 17. The method of claim 1, further comprising the steps of: providing a data analysis system; and connecting said data analysis system to said data acquisition system for processing digital measurement signals and for removing and isolating extraneous noises.
 18. The method of claim 17, further comprising the steps of: processing said digital measurement signals with said data acquisition system to monitor and analyze a variety of bodily functions, including patient heart beat, fetal heart beat, breathing, labor contractions, ureteral flow and physiology of the bladder, digestive, urologic, pulmonary, cardiovascular and neurologic systems.
 19. The method of claim 18, further comprising the step of: storing raw or processed measurement signal data in a digital memory device.
 20. The method of claim 19, further comprising the step of: displaying said stored raw or processed measurement signal data in a graphical display.
 21. The method of claim 1, further comprising the step of: providing said data acquisition system in the form of a hand-held computational device.
 22. The method of claim 1, further comprising the step of: covering said housing with sound absorbing materials to shield it from ambient noise.
 23. The method of claim 1, further comprising the step of: actively cancelling ambient noise by employing at least one external microphone in combination with said at least one transducer.
 24. The method of claim 1, further comprising the step of: actively cancelling extraneous body noises or pressure fluctuations by employing at least one acoustic or at least one pressure measurement transducer positioned externally on a patient's body in combination with said at least one transducer.
 25. The method of claim 1, further comprising the step of: sterilizing said housing and said at least one transducer for subsequent use.
 26. The method of claim 1, further comprising the step of: providing said housing and said at least one transducer in disposable form.
 27. The method of claim 1, further comprising the step of: providing said at least one transducer in the form of a Doppler ultrasound transceiver. 